KR20150038187A - Spindle drive - Google Patents

Abstract

The present invention relates to a spindle drive for linear movement of a drive rod. The spindle drive includes a threaded spindle, a threaded nut interacting with the threaded spindle, and a coupling block coupled to the drive rod and the threaded nut and having a recess in which the threaded nut is disposed. According to the invention, the coupling block and the threaded nut are threaded by the locking bore in such a way that the locking bolt inserted into the locking bore locks the threaded nut in an unrotatable and non-displaceable way in the recess. Such a spindle driving part can be assembled simply without a tool.

Description

[0001] SPINDLE DRIVE [0002]

The present invention relates to a spindle drive according to the preamble of claim 1 and to a component of a gas insulated switchgear according to claim 4.

The gas insulated switchgear comprises a plurality of different components that are sealed together or separately with other components within the hermetic housing. When such gas insulated switchgear is inspected or maintained, the electrical connections of many components must be disconnected from the switchgear for this purpose. These components may be, for example, transducers or surge arresters.

A spindle drive is known in which the electrical connection can be opened and closed when the housing is closed and a spindle guided through the housing in an airtight manner in the spindle drive is driven by a crank handle from the outside of the housing And moves the drive rod which opens or closes the contact of the interruption point inside the housing. At this time, the connection between the spindle and the driving rod is made, for example, by adhesive bonding or pin bonding. This has the disadvantages that the connection can no longer be released, must be handled in a small space by tools, or metal shaves can occur during assembly.

It is therefore an object of the present invention to propose a spindle drive which can be easily assembled in a limited space and has a releasable connection between the spindle and the drive rod.

This problem is solved by the spindle driver according to claim 1.

At this time, the spindle driving part for linear movement of the driving rod has a screw spindle and a screw nut interacting with the screw spindle. The drive rod and the screw nut are connected to a coupling block having a recess in which the screw nut is disposed. According to the invention, the coupling block and the threaded nut are pierced by the locking bore in such a way that the locking bolt inserted into the locking bore locks the threaded nut in a non-rotatable and non-displaceable manner in the recess. Therefore, the locking bolt and the recess can have the same diameter, and the screw nut can have a recess that is in a form-fitting contact with the shank of the locking bolt. At this time, the locking bore may penetrate the threaded nut in the form of a bore entirely or only partially in the form of a recess on the outer surface of the threaded nut. Such a spindle drive can be particularly simple to assemble, and the locking bolt is removed, thereby enabling the release of the connection.

In a preferred embodiment of the present invention, the drive rod projects into the bore of the coupling block. The coupling block and the drive rod are pierced by the locking bore in such a way that the locking bolt inserted into the locking bore locks the driving rod in a non-rotatable and non-displaceable manner within the recess. At this time, the drive rod may be penetrated by the locking bore in the form of a bore like a screw nut, or may be penetrated only by a recess corresponding to the locking bore on the outer surface. As a result, the drive rod is connected to the coupling block in a manner similar to a screw nut. The mentioned advantages also apply here. If the bore and locking bolts are designed in a similar way, a particularly simple formation of both connection methods is possible.

Preferably, the locking bore penetrates the coupling block, the screw nut, and the drive rod in such a manner that the locking bolt inserted into the locking bore locks not only the screw nut but also the driving rod and is displaceably locked. If not only the screw nut but also the drive rod are provided with recesses on their outer surface, such a screw nut and drive rod can be arranged on opposite sides with respect to the longitudinal axis of the locking bore. If a screw nut or drive rod is provided with a bore shaped recess, such a screw nut or drive rod may be continuously disposed along the longitudinal axis of the locking bore. However, it is also possible for the drive rod to project into the screw nut bore intersecting the locking bore at right angles. At this time, the driving rod has a bore corresponding to the locking bore, which is penetrated by the locking bolt. At this time, the intersecting volume of the locking bolt and the driving rod is located in the screw nut. In this way, the screw nut and the drive rod are jointly connected to the coupling block by a single locking bolt in a particularly simple manner. This reduces the number of required components and assembly costs.

In a further preferred embodiment of the invention, the component for the gas insulated switchgear comprises a hermetically sealed housing, in which an interruption point is arranged which can be actuated by a drive rod which can be moved. At this time, the driving rod can be moved from the outside of the housing by the spindle driving unit according to the present invention, as described above. Since the spindle drive is located inside the housing of the components and has to be assembled there as well, the simple, toolless and therefore shaving-free assembly of the spindle drive part particularly preferably affects the reliability of the components, Metal shaving that occurs can cause flashovers of components and result in functional errors.

In addition, in a preferred embodiment of the present invention, it is provided that the components are surge arresters or converters. In the case of these types of components, the space conditions provided for assembly are frequently reduced, so that easy assembly of the spindle driver is particularly desirable here.

In the following, the invention is explained in more detail by the figures.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 illustrates the use of a conventional type of spindle driver within a surge arrester, in accordance with the prior art.
2 is a perspective view of a spindle driving unit according to the present invention.
3 is a perspective view of the individual components of the spindle drive according to the present invention.
4 is a plan view of the spindle driving unit according to FIG.
Figure 5 is a front view corresponding to Figure 4;
Figure 6 is a view corresponding to Figure 5, showing an alternative embodiment of the present invention.

Corresponding parts are provided with the same reference numerals in all figures.

1 is a cross-sectional view of the surge arresters 40. A discharge element 20 is disposed in a fluid-tight housing 41. The discharge element 20 includes a cylindrical varistor column 25, a top fixing body 22, a bottom fixing body 21, and a plurality of tension members 23. At both ends of the varistor column 25, there are single solids 21 that can be seen only in the lower solids 21 in FIG. The tension members 23 are pressed under tension in the single fixtures 21 to join the varistor column 25. Fixing disks 24 with holes are inserted into the varistor column 25 and the tension members 23 are guided through the holes to further strengthen the discharge elements 20. [

The housing 41 is substantially cylindrical. The longitudinal axis 50 extends along the cylindrical axis. The discharge elements 20 are aligned along this longitudinal axis 50. On both cover surfaces, the housing 41 is closed in a liquid-tight manner.

The cover surface of the housing 41 on the ground side of the discharge element 20 is closed by the simple housing cover 42. [ The grounding portion 48 is electrically insulated by the housing cover 42, guided to the outside from the inside of the housing 41, and used for grounding. In the interior of the housing 41, this grounding portion 48 is connected to the discharge element 20 by, for example, a cable 15 so as to be electrically conductive.

The high voltage connection side of the discharge element 20 is provided with a high-voltage bushing (not shown) on the cover surface of the housing 41 for guiding the high voltage potential from the outside into the housing 41 without risk of flashover between the high voltage and the grounded housing 41. [ voltage bushing 45 is provided. Inside the housing 41, the high voltage bushing 45 has a contact 49.

A corresponding contact portion 47 electrically connected to the high voltage side end portion of the discharge element 20 is connected to the driving portion 30 and the driving portion includes a spindle 31 guided to pass through the housing cover 42 in a liquid- And is driven by a crank handle 34 connected to the spindle 31 outside the housing 41.

Through the crank handle 34, the spindle 31 can be converted into rotary motion. This rotational motion through the drive 30 is converted into a linear motion of the drive rod 33 in the direction of the longitudinal axis 50. The driving rod 33 again transmits this linear movement to the corresponding contact 47. [ For better guidance of the drive rod 33, the drive rod is guided through the holes in the stationary discs 24. Therefore, the corresponding contact 47 can be moved toward and away from the contact 49 in the direction of the longitudinal axis 50, so that the electrical connection can be made or stopped. In the drawing of Fig. 1, the electrical connection is interrupted.

In Fig. 2, the spindle drive 1 according to the present invention is shown in a combined form and is shown in the corresponding exploded view in Fig. 4 and 5 show different views of the spindle drive 1 shown in Fig. The illustrated spindle drive part 1 has a screw spindle 3 which is switched to rotation, for example, by a crank handle, as shown in Fig. A corresponding threaded nut 4 interacts with the threaded spindle 3. At this time, the threaded nut 4 has an internal thread, and the threaded spindle 3 has a corresponding external thread, for example, a trapezoidal thread. When the threaded spindle 3 is rotated and the threaded nut 4 is prevented from rotating together with the threaded spindle 3, the threaded nut 4 is moved along the threaded spindle 3. The direction of the movement is determined by the rotational direction of the screw spindle 3. [ Therefore, the rotational movement of the threaded spindle 3 is converted by the spindle driving part 1 into the linear movement of the threaded nut 4. [

The coupling block 5 connects the screw nut 4 and the drive rod 2 to transfer the linear motion to the drive rod 2. To this end, the coupling block 5 has three bores 9, 10, 6. A drive rod 2 having an end protrudes into the bore 9. The threaded spindle 3 extends through a spindle bore 10 extending parallel to these bores 9 and completely passing through the coupling block 5. The spindle bore 10 has a coaxial recess 8 in one of its openings through which the threaded nut 4 can be inserted. The locking bore 6 extends laterally through the coupling block 5 to the bore 9 and the spindle bore 10. At this time, the locking bore 6 crosses not only the recess 8 but also the bore 9. Alternatively, two locking bores 6 parallel to one another may be considered, one of the locking bores intersecting the recess 8, and the other locking bore of the bore 9 Intersect. The locking bore 6 is located between the spindle bore 10 with the recess 8 and the bore 9 and is positioned between the bore 9 and the recess 8 by the locking bore 6. [ Are opposite to each other with respect to the locking bore 6. Alternatively, it is possible to arrange the spindle bore 9 with the recess 8 and the bore 9 continuously on one side of the locking bore 6. In Fig. 6, a diagram corresponding to Fig. 5 of this embodiment is shown.

The screw nut (4) has a recess (11). This recess is formed in such a way that the screw nut 4 can be inserted into the recess 8 so that the recess 11 is located in the intersection area of the recess 8 with the locking bore 6. [ As shown in FIG. When the locking bolt 7 is inserted into the locking bore 6, the screw nut 4 is not rotatable in the form-fitting manner and is locked in the recess 8 in a non-displaceable manner. The same locking principle applies to the drive rod 2 as well. Likewise, this drive rod has a recess 12 in a portion of its outer surface, which is inserted into the bore 9. This recess is arranged such that the drive rod can be inserted into the bore 9 in such a way that the recess 12 is located at the intersection of the bore 9 and the locking bore 6. [ When the locking bolt 7 is inserted into the locking bore 6, this causes the driving rod 2 to be locked in the bore 9 in a non-rotatable and non-displaceable manner. At this time, the screw nuts 4 and the driving rod 2 may be provided with respective locking bores 6 and locking bolts 7, respectively, or as shown in Figs. 2 to 6, One locking bolt 7 in the screw 6 can lock not only the screw nut 4 but also the driving rod 2.

All the bores 6, 9, 10 and all of the recesses 8, 11, 12 can be made of simple tools such as drills and circular mills. Assembly of the spindle driving part 1 is possible without a tool. First, the threaded nut 4 is inserted into the threaded spindle 3 and becomes a desired height. The coupling block 5 with the spindle bore 10 is then inserted into the threaded spindle 3 and is threaded along the threaded spindle 3 until the threaded nut 4 is in the recess 8 . Then, the end of the drive rod 2 is inserted into the bore 9. The drive rod 2 and the screw nut 4 are now aligned so that their recesses 11 and 12 are located in the opening of the locking bore 6. [ Now, the locking bolt 7 is inserted into the locking bore 6, whereby the screw nut 4 and the driving rod 2 are locked. The locking bolt 7 has a bolt head as a depth stop at one end and protrudes from the locking bore 6 at the other end and is provided with cotter pins, such as cable ties, to prevent slipping. At the same time, the bolt head is used as a handle for simply releasing the connection.

Claims (5)

A spindle drive (1) for linear movement of a drive rod (2), the spindle drive comprising a threaded spindle (3), a threaded nut (4) interacting with the threaded spindle, a drive rod (2) (5) having a recess (8) in which a screw nut (4) is disposed, the spindle driving part being connected to the spindle (4)
The coupling block 5 and the threaded nut 4 are arranged in such a way that the locking bolt 7 inserted into the locking bore 6 is not rotatable and immovably locks the threaded nut 4 in the recess 8 Is passed through by a locking bore (6). 2. A locking device according to claim 1, characterized in that the driving rod (2) protrudes into the bore (9) of the coupling block (5) and the coupling block (5) and the driving rod (2) Characterized in that the bolt (7) is penetrated by the locking bore (6) in such a manner that the driving rod (2) is not rotatable and is displaceably locked in the bore (9). The locking bore (6) according to claim 1 or 2, wherein the locking bolt (7) inserted into the locking bore (6) is not rotatable but displaceable not only in the screw nut (4) but also in the driving rod (4), and the drive rod (2) in such a manner as to lock the coupling block (5), the screw nut (4) and the drive rod (2). Components for a gas-insulated switchgear with a hermetic housing, in which a shut-off point is arranged which can be actuated by a drive rod (2) which can be moved, wherein the drive rod (2) Components which can be moved from the outside of the housing by means of the spindle drive part (1) according to claims 1 to 3, 5. The components of claim 4, wherein the components are surge arresters or transducers.

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